Low profile rear derailleur with cable guide

ABSTRACT

A bicycle rear derailleur comprises a base member; a movable member that supports a chain guide including a first pulley that rotates around a first pulley axis, wherein the pulley has a pulley plane; a first linking member coupled between the base member and the movable member so that the chain guide moves laterally relative to the base member between a first lateral position and a second lateral position, and a cable guide supported to the base member to guide a shift control cable. The pulley plane intersects the first linking member when the chain guide is located at a first position between the first lateral position and the second lateral position.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of copending application Ser. No. 11/307,941, filed Feb. 28, 2006.

BACKGROUND OF THE INVENTION

The present invention is directed to bicycles and, more particularly, to a low profile rear derailleur used to switch a chain among a plurality of sprockets that rotate with the rear wheel.

A bicycle rear derailleur is used to selectively engage a chain with one of a plurality of sprockets that rotate with the rear wheel of the bicycle. A typical rear derailleur comprises a base member, a movable member supporting a chain guide, and a linking mechanism coupled between the base member and the movable member so that the chain guide moves laterally relative to the base member. The base member usually is mounted to the rear end of the bicycle frame by a mounting bolt that screws into a threaded opening formed in the frame. Because of the nature of the lateral movement of the chain guide required to switch the chain among the sprockets, the linking mechanism, the movable member and the chain guide all protrude laterally outward by a significant distance, especially when the chain is engaged with the laterally outermost rear sprocket. As a result, the chain guide is susceptible to striking or becoming entangled with nearby objects, especially when riding off-road in mountainous terrain. The effect becomes more severe as the number of sprockets increase.

SUMMARY OF THE INVENTION

The present invention is directed to various features of a bicycle rear derailleur. In one embodiment, a bicycle rear derailleur comprises a base member; a movable member that supports a chain guide including a first pulley that rotates around a first pulley axis, wherein the pulley has a pulley plane; a first linking member coupled between the base member and the movable member so that the chain guide moves laterally relative to the base member between a first lateral position and a second lateral position, and a cable guide supported to the base member to guide a shift control cable. The pulley plane intersects the first linking member when the chain guide is located at a first position between the first lateral position and the second lateral position. Additional inventive features will become apparent from the description below, and such features alone or in combination with the above features may form the basis of further inventions as recited in the claims and their equivalents.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a laterally outer view of a particular embodiment of a rear derailleur in a high speed position;

FIG. 2 is a laterally inner view of the derailleur;

FIG. 3 is a top view of the derailleur in the high speed position;

FIG. 4 is a bottom view of the derailleur in the high speed position;

FIG. 5 is a front view of the derailleur in the high speed position;

FIG. 6 is a rear view of the derailleur in the high speed position;

FIG. 7 is a side view of the derailleur in a low speed position;

FIG. 8 is a top view of the derailleur in the low speed position;

FIG. 9 is a bottom view of the derailleur in the low speed position;

FIG. 10 is a front view of the derailleur in the low speed position;

FIG. 11 is a rear view of the derailleur in the low speed position; and

FIG. 12 is a laterally outer view of the rear derailleur attached to a conventional frame;

FIG. 13 is a laterally outer view of another embodiment of a rear derailleur attached to a conventional frame;

FIG. 14 is a more detailed view of the base member and cable guide;

FIG. 15 is a view taken along line 15-15 in FIG. 14;

FIG. 16 is a rear elevational view of the derailleur mounting boss; and

FIG. 17 is a rear elevational view of the base member.

DETAILED DESCRIPTION OF THE EMBODIMENTS

FIGS. 1-11 are various views of a particular embodiment of a low profile derailleur 10 in various positions. For example, FIG. 1 is a laterally outer view of rear derailleur 10, and FIG. 2 is a rear view of derailleur 10. As shown in FIG. 1, rear derailleur 10 is attached to the rear portion of a bicycle frame 14 for guiding a chain 18 among a plurality of rear sprockets R1-R8 that rotate coaxially around a rear wheel axle 22 supported to frame 14, wherein axle 22 defines a rotational axis X.

Bicycle frame 14 is part of an overall bicycle frame that includes a chain stay 26, a seat stay 30 and a frame end 34 (commonly referred to as a dropout) that joins chain stay 26 and seat stay 26 together, typically by welding chain stay 26 and seat stay 30 to frame end 34. Conceptually, each of these frame structures is well known. However, this embodiment employs a configuration of frame end 34 that differs from common frame ends. More specifically, frame end 34 comprises a forward portion 38 and a rearward portion 42, wherein forward portion 38 extends from chain stay 26 and seat stay 30 to a horizontal position aligned with rotational axis X, and rearward portion 42 extends from the horizontal position aligned with rotational axis X rearward. A junction between forward portion 38 and rearward portion 42 forms an axle receiving slot 46 dimensioned to receive rear axle 22 therein. In this embodiment, axle receiving slot 46 is oriented substantially vertical with a slight incline and includes an open end 50 and a closed end 54, wherein open end 50 is disposed below closed end 54. Rearward portion 42 extends rearward and downward at an incline and forms a derailleur attachment structure in the form of a laterally projecting annular mounting boss 58 with an opening 60 dimensioned to receive a derailleur mounting bolt 62 therein. Of course, in some embodiments mounting boss 58 need no project laterally, in which case the surface of opening 60 forms the derailleur attachment structure. In this embodiment, opening 60 may be located from approximately 180° to approximately 240° relative to rotational axis X, or, to facilitate measurement independently of axle 22, from approximately 180° to approximately 240° relative to closed end 54 of axle receiving slot 46. Rearward portion 42 of frame end 34 extends further rearward from mounting boss 58 to form a position setting abutment 66 that functions in a manner discussed below.

Derailleur 10 comprises a base member 70, a movable member 74 that supports a chain guide 78, and a linking mechanism 82 coupled between base member 70 and movable member 74 so that chain guide 78 moves laterally relative to base member 70. As best seen in FIGS. 2 and 3, base member 30 comprises an annular mounting boss 86 with a mounting surface 90 that faces laterally outward to face mounting boss 58 on frame end 34, a transition portion 94 that extends rearward and downward at an incline from mounting boss 86, and a link coupling portion 98 disposed at a lower end portion of extension portion 94.

As best seen in FIGS. 1 and 3, an adjuster mounting boss 99 extends rearward and then laterally outward from mounting boss 86. A laterally outer portion of adjuster mounting boss 99 includes an adjuster mounting structure in the form a threaded opening 100 dimensioned to threadingly engage an adjuster in the form of an adjusting screw 101. The tip of adjusting screw 101 abuts against position setting abutment 66 on frame end 34. Thus, the rotational position between frame end 34 and base member 70 may be adjusted simply by rotating adjusting screw 101.

An outer casing coupler 102 in the form of a hollow cylinder is disposed on an upper portion of transition portion 94, wherein outer casing coupler 102 is dimensioned to couple to and terminate an outer casing 106 of a Bowden cable 110 in a known manner. Outer casing coupler 102 is positioned to be located rearward from rotational axis X and, more particularly, rearward from frame end 34 and at least partially laterally inward from mounting surface 90 of base member 70 as shown in FIG. 3. Outer casing coupler 102 includes an outer casing receiving bore 104 having a bore axis B that is inclined relative to a pulley plane P described below. If desired, a cable adjusting bolt (not shown), the concept and structures of which are well known, may be mounted in outer casing receiving bore 104 so as to be disposed between outer casing coupler 102 and outer casing 106.

As shown in FIGS. 1 and 2, link coupling portion 98 includes a support wall 114, an outer link mounting ear 118 and an inner link mounting ear 122. In this embodiment, inner link mounting ear 122 is formed as an extension of transition portion 94 that inclines laterally inwardly from front to rear and from top to bottom, support wall 114 extends laterally outwardly from inner mounting ear 122 so as to incline rearwardly from top to bottom and from transition portion 94 to the laterally outer end, and outer link mounting ear 118 extends downwardly from support wall 114 so as to incline laterally inwardly from front to rear and from top to bottom.

Movable member 74 comprises a main body 130 and a link mounting frame 134. In this embodiment, main body 130 comprises a generally cylindrical member that houses a torsion coil spring 138, one end of which is inserted into a spring mounting opening 142 formed in a laterally outer side wall 146 of main body 130. Link mounting frame 134 comprises an upper link mounting boss 150, a lower link mounting boss 154, and an upper chain guide link mounting frame 158, all of which are formed as one piece with main body 130.

Linking mechanism 82 comprises linking members in the form of a laterally outer upper link 162 and a laterally inner lower link 166. A first end of upper link 162 is straddled by link coupling portion 98 of base member 70 and is pivotably connected thereto by a pivot shaft 170 that defines a pivot axis P1. The second end of upper link 162 is forked to straddle upper link mounting boss 150 of link mounting frame 134 of movable member 74 and is pivotably connected thereto by a pivot shaft 174 that defines a pivot axis P2. Because of this arrangement, a distance between the outermost edges of the first end of upper link 162 at base member 70 is less than a distance between the outermost edges of the second end of upper link 162 at movable member 74. An outer limit adjusting screw 186 and an inner limit adjusting screw 190 are mounted on upper link 162 to adjust the laterally outermost and laterally innermost positions of movable member 74, respectively, in a well known manner.

Similarly, a first end of lower link 166 is straddled by link coupling portion 98 of base member 70 and is pivotably connected thereto by a pivot shaft 178 that defines a pivot axis P3. An actuating arm 175 extends downwardly and laterally inwardly from the first end of lower link 166 so as to generally conform to the inclined contour formed by the outer peripheral surfaces of the plurality of sprockets R1-R8. A cable attachment structure in the form of a bolt 176 and a clamping washer 177 is provided at the outer end of actuating arm 175 to attach a shift control cable such as an inner cable 108 of Bowden cable 106, for example, as shown in FIG. 2. As shown in FIG. 3, bolt 176 and washer 177 are disposed laterally inward from mounting surface 90 of base member 70 when chain guide 78 is located at a laterally outermost position.

Lower link 166 is forked beginning in close proximity to pivot shaft 178 to form legs 179 and 180 (FIG. 2) that extend toward movable member 74. Legs 179 and 180 straddle lower link mounting boss 154 of link mounting frame 134 of movable member 74 and is pivotably connected thereto by a pivot shaft 182 (FIG. 1) that defines a pivot axis P4. Because of this arrangement, a distance between the outermost edges of the first end of lower link 166 at base member 70 is less than a distance between the outermost edges of the second end of lower link 166 at movable member 74.

As shown in FIG. 2, legs 179 and 180 of lower link 166 receive a coiled return spring 181 therebetween. One end of spring 181 is connected to base member 70 at pivot shaft 170, and the other end of spring 181 is connected to movable member 74 at pivot shaft 182. As a result, spring 181 biases movable member 74 laterally outwardly.

Chain guide 78 comprises an upper chain guide link 194, a first or upper guide pulley 198 rotatably mounted to upper chain guide link 194 through a pivot shaft 200, a lower chain guide link 202, and a second or lower tension pulley 206 rotatably mounted to lower chain guide link 202 through a pivot shaft 208. Upper chain guide link 194 is pivotably connected to upper chain guide link mounting frame 158 through a pivot shaft 210. Upper chain guide link 194 comprises a chain pushing member 214 and a chain regulating unit 218. Chain pushing member 214 is disposed between upper chain guide link mounting frame 158 and guide pulley 198, with an arcuate portion 222 disposed in close proximity to the teeth on guide pulley 198. Chain pushing member 214 is provided to push chain 18 when switching chain 18 from a smaller diameter sprocket to a larger diameter sprocket and to prevent chain 18 from derailing from guide pulley 198. Chain pushing member 214 rotates around a chain pushing member rotational axis defined by pivot shaft 210, which in this embodiment is offset from a first pulley axis defined by pivot shaft 200. As a result, both guide pulley 198 and chain pushing member 214 rotate around the chain pushing member rotational axis defined by pivot shaft 210.

Chain regulating unit 218 comprises an inner plate 226, an outer plate 230 and a regulator pin 234. A radially inner end of inner plate 226 is coupled to pivot shaft 200, and a radially outer end of inner plate 226 is fastened to one end of regulator pin 234. A radially inner portion of outer plate 230 joins with chain pushing member 214 and is coupled to pivot shaft 210, and a radially outer end of outer plate 230 is fastened to the other end of regulator pin 234. Inner plate 226 helps to prevent chain 18 from derailing from guide pulley 198 when switching chain 18 from a larger diameter sprocket to a smaller diameter sprocket, and outer plate 230 helps to prevent chain 18 from derailing from guide pulley 198 when switching chain 18 from a smaller diameter sprocket to a larger diameter sprocket. Regulator pin 234 helps to prevent excessive radial movement of chain 18 and ensures that upper chain guide link 194 rotates counterclockwise around pivot shaft 210 in response to forward swinging of chain 18. However, chain regulating unit 218 may be omitted in some embodiments.

As shown in FIG. 2, an upper end 205 of lower chain guide link 202 is pivotably coupled to main body 130 of movable member 74 through a pivot shaft 238 and includes a plurality of, e.g., three spring coupling openings 242. The other end of spring 138 mentioned above is inserted into one of the spring coupling openings 242 to set a desired biasing force on lower chain guide link 202. As a result, lower chain guide link 202 is biased clockwise in FIG. 1. A lower end 207 of lower chain guide link 202 rotatably supports tension pulley 206 through pivot shaft 208 and nonrotatably supports a chain regulating unit 248. In this embodiment, as shown in FIG. 4, upper end 205 is substantially vertically straight and is laterally inwardly offset relative to lower end 207, which also is substantially vertically straight. As with chain regulating unit 218, chain regulating unit 248 comprises an inner plate 252, an outer plate 256 and a regulator pin 260. A radially inner end of inner plate 252 is coupled to pivot shaft 208, and a radially outer end of inner plate 252 is fastened to one end of regulator pin 260. In this embodiment, outer plate 256 is formed as a part of lower chain guide link 202 and supports pivot shaft 208. A radially outer end of outer plate 256 is fastened to the other end of regulator pin 260. Inner plate 252 helps to prevent chain 18 from derailing from tension pulley 206 when switching chain 18 from a larger diameter sprocket to a smaller diameter sprocket, and outer plate 256 helps to prevent chain 18 from derailing from tension pulley 206 when switching chain 18 from a smaller diameter sprocket to a larger diameter sprocket. Regulator pin 260 helps to prevent excessive radial movement of chain 18. Chain regulating unit 248 may be omitted in some embodiments.

In this embodiment, base member 70, movable member 74, chain guide 78 and linking mechanism 82 are dimensioned so that guide pulley 198 is located at a range of from approximately 220° to approximately 270° relative to rotational axis X when chain guide 78 is disposed in the laterally outermost position.

As shown in FIG. 4, guide pulley 198 has a pulley plane P that bisects guide pulley 198. In this embodiment, each tooth on guide pulley 198 is symmetrical and centered on the pulley when viewed perpendicular to pivot shaft 200 so that pulley plane P is located in the center of guide pulley 198, and all of the pulley teeth lie in pulley plane P. In this embodiment, pulley plane P also bisects tension pulley 206. In order to provide a decreased laterally outward profile for derailleur 10, the components are structured so that pulley plane P intersects at least one of upper link 162 or lower link 166 when chain guide 78 is disposed in a position somewhere between a laterally outermost rest position and a laterally innermost position (such as the laterally outermost position shown in FIG. 4).

As used throughout herein, the word “intersect” has the ordinary meaning of having one or more points in common. Thus, the term also includes, for example, a tangent relationship. The laterally outermost position may be the laterally outermost position when derailleur 10 is removed from the bicycle. In this case, the laterally outermost position may be determined by the position of chain guide 78 with the derailleur at rest and subjected only to the biasing force of return spring 181, and the laterally innermost position is determined by the position of chain guide 78 when chain guide 78 is manually pulled to its laterally innermost position. Alternatively, the laterally outermost position may be determined by the position of chain guide 78 when it is set to be aligned with the smallest diameter rear sprocket R1, and the laterally innermost position may be determined by the position of chain guide 78 when it is set to be aligned with the largest diameter rear sprocket R8. The word “between” is used in an inclusive sense.

Furthermore, in this embodiment, pulley plane P intersects at least one of pivot axis P1 or pivot axis P3 when measured across all components at the coupling when chain guide 78 is disposed in a position somewhere between a laterally outermost rest position and a laterally innermost position (such as the laterally outermost position shown in FIG. 6). For example, pivot shaft 170 defines pivot axis P1 and couples upper link 162 to base member 70. The laterally outer tip of pivot shaft 170 is exposed at outer link mounting member 118, whereas the laterally inner tip of pivot shaft 170 is inserted into a blind bore (not shown) in inner link mounting member 122 so that the inner lateral tip is not exposed at inner link mounting member 122. The length of pivot axis P1 measured across all components at the coupling therefore extends from the laterally outer tip of pivot shaft 170 at pivot axis P1 to the laterally inner surface of inner link mounting member 122 at pivot axis P1. Similarly, pivot shaft 178 defines pivot axis P3 and couples lower link 166 to base member 70. The laterally outer tip of pivot shaft 178 is exposed at outer link mounting member 118, whereas the laterally inner tip of pivot shaft 178 is inserted into a blind bore (not shown) in inner link mounting member 122 so that the inner lateral tip is not exposed at inner link mounting member 122. The length of pivot axis P3 measured across all components at the coupling therefore extends from the laterally outer tip of pivot shaft 178 at pivot axis P3 to the laterally inner surface of inner link mounting member 122 at pivot axis P3.

In this embodiment, pulley plane P intersects both upper link 162 and lower link 166 as well as pivot axes P1 and P3 when chain guide 78 is disposed in a position somewhere between the laterally outermost position and the laterally innermost position, such as the laterally outermost position shown in FIG. 4. However, it is not necessary to intersect all recited components at all lateral positions of chain guide 78. For example, while at least one of pivot axes P1-P4 is disposed on a laterally inner side of pulley plane P, and at least one of pivot axes P1-P4 is disposed on a laterally outer side of pulley plane P, in this embodiment second pivot axis P2 as measured according to the definition above is disposed entirely on the laterally outer side of pulley plane P (as well as movable member plane M) in the position shown in FIG. 3. In this embodiment, pulley plane P intersects a space S1 between any facing surfaces (e.g., surfaces 261 and 262 shown in FIG. 2) of upper link 162 and lower link 166 as shown in FIG. 4. Pulley plane P also intersects base member 70 when chain guide 78 is disposed in a position somewhere between the laterally outermost position and the laterally innermost position, such as the laterally outermost position shown in FIG. 3.

As shown further in FIG. 4 (with spring 181 removed for clarity), a movable member plane M that is substantially parallel to pulley plane P intersects an innermost surface 264 of movable member 74. In this embodiment, innermost surface 264 is coplanar with movable member plane M, although other configurations are possible since movable member 74 may have many different shapes. Movable member plane M intersects both upper link 162 and lower link 166, pivot axes P1 and P3, and the space S1 between facing surfaces of upper link 162 and lower link 16 when chain guide 78 is disposed in a position somewhere between the laterally outermost position and the laterally innermost position. Furthermore, at least a portion of a space S2 between movable member plane M and pulley plane P intersects the space S1 between facing surfaces of upper link 162 and lower link 16 when chain guide 78 is disposed in a position somewhere between the laterally outermost position and the laterally innermost position, such as the laterally outermost position shown in FIG. 4.

As shown in FIGS. 3 and 8, derailleur 10 has a very low lateral profile. For example, when chain guide 78 is located in the laterally outermost position shown in FIG. 3, the components barely protrude laterally outward relative to frame 14. Actuating arm 175 and portions of linkage mechanism 82 are disposed laterally inward from pulley plane P and movable member plane M and follow the diagonal contour of sprockets R1-R8, thereby forming a very compact structure. When chain guide 78 is located in the laterally innermost position shown in FIG. 8, mounting boss 58 is the laterally outermost portion of derailleur 10. In fact, mounting boss 58 does not even protrude laterally outward relative to chain stay 26 or seat stay 30. In this position, actuating arm 175 and linkage mechanism 82 again following the diagonal contour of sprockets R1-R8.

Prior art derailleurs do not have the ability to have such a low profile. One reason is that the chain guide in prior art derailleurs has a chain pushing member that is formed as one piece with an inner plate that extends from the upper guide pulley to the lower tension pulley, and this inner plate limits the ability of the chain guide to move laterally outwardly. In the presently disclosed embodiment, chain pushing member 214 is dimensioned to as not to interfere with the ability of chain guide 78 to move laterally outwardly. The two-piece structure of chain guide 78 further facilitates such lateral movement. Furthermore, the base member and linking mechanism in prior art derailleurs are dimensioned to be mounted substantially below, or even in front of, the rotational axis X of the rear wheel, and this requires sufficient lateral spacing to ensure that the linking mechanism does not strike the sprockets during operation. Since base member 70, upper link 162, lower link 166 movable member 74 and chain guide 78 in the presently disclosed embodiment are dimensioned so that guide pulley 198 is located at a range of from approximately 220° to approximately 270° relative to rotational axis X when chain guide 78 is disposed in the laterally outermost position, the lateral distance required for the components further decreases because the linking mechanism is able to more closely follow the contour formed by the outer peripheral surfaces of the plurality of sprockets R1-R8. Of course, while many of the features described herein contribute to a markedly low profile derailleur, not all features are required, depending upon the application.

FIG. 12 is a laterally outer view of rear derailleur 10 mounted to a frame end 300 of a conventional frame 14′. In this case, frame end 300 comprises a forward portion 304 and a rearward portion 308, wherein forward portion 304 extends from chain stay 26 and seat stay 30 to a horizontal position aligned with rotational axis X, and rearward portion 308 extends from a horizontal position aligned with rotational axis X rearwardly and substantially vertically downwardly. A junction between forward portion 304 and rearward portion 308 forms an axle receiving slot 312 dimensioned to receive rear axle 22 therein. In this embodiment, axle receiving slot 312 again is oriented substantially vertically with a slight incline and defines an open end 316 and a closed end 320, wherein open end 316 is disposed below closed end 320. Rearward portion 308 forms an annular mounting boss 324 with an opening (not shown) dimensioned to receive a mounting bolt 328 therein.

Derailleur 10 is mounted to an extension member 330 having a first end portion 334 and a second end portion 338, wherein first end portion 334 includes a mounting opening 342 dimensioned for receiving mounting bolt 346 therein. Second end portion 338 includes a derailleur attachment structure in the form of a derailleur mounting opening 350 dimensioned for receiving mounting bolt 62 therethrough. Extension member 330 is dimensioned such that, when extension member 330 is attached to frame end 300, mounting opening 350, and hence boss member 86 of base member 70 of derailleur 10, is located from approximately 180° to approximately 240° relative to axle receiving opening 312, from approximately 180° to approximately 240° relative to rotational axis X, or, to facilitate measurement independently of axle 22, from approximately 180° to approximately 240° relative to closed end 320 of axle receiving opening 312. Rearward portion 38 extends further rearwardly from derailleur mounting opening 350 to form a position setting abutment 354 that functions in the same manner as position setting abutment 66 in the first embodiment.

FIG. 13 is a laterally outer view of another embodiment of a rear derailleur 10′ attached to frame end 300 of conventional frame 14′. Rear derailleur 10′ has the features described for derailleur 10 in FIG. 12 except for a different extension member 330′ and a modified base member 70′ that supports a cable guide unit 400. Also, in this embodiment chain guide 78 is biased toward the largest rear sprocket R8 (by switching the ends of return spring 181 to pivot shafts 174 and 178), so inner cable 108 is attached to a cable clamp 404 fixed to upper link 162.

Extension member 330′ has a first end portion 334 and a modified second end portion 338′, wherein first end portion 334 includes mounting opening 342 dimensioned for receiving mounting bolt 346 therein. Second end portion 338′ includes a derailleur attachment structure in the form of a derailleur mounting boss 408 (FIGS. 15 and 16) dimensioned for supporting base member 70′. Extension member 330′ is dimensioned such that, when extension member 330′ is attached to frame end 300, derailleur mounting boss 408, and hence base member 70′, is located from approximately 180° to approximately 240° relative to axle receiving opening 312, from approximately 180° to approximately 240° relative to rotational axis X, or from approximately 180° to approximately 240° relative to closed end 320 of axle receiving opening 312.

As shown more clearly in FIG. 16, derailleur mounting boss 408 includes an inner end face 444, an outer end face 445, and a step-shaped outer peripheral surface 446 extending between end faces 444 and 445. End faces 444 and 445 are axially opposed, with inner end face 444 forming a portion of the inner side of extension member 330′. Outer end face 445 has a centrally located threaded fastener opening 449 and three axially extending projections 450. Fastener opening 449 is arranged and configured to receive a fixing bolt 451 (FIG. 15) for attaching cable guide unit 400 in a non-rotatable manner. Projections 450 are generally arc-shaped members arranged on an imaginary circle that is coaxially arranged relative to fastener opening 449. Outer peripheral surface 446 comprises four outer peripheral surfaces 452, 453, 454 and 455 with progressively decreasing diameters. Three axially outwardly facing end surfaces 456, 457 and 458 are disposed between adjacent pairs of outer peripheral surfaces 452, 453, 454 and 455. A stopper member 448 is disposed at the lower portion of outer peripheral surface 452.

As shown in FIG. 17, base member 70′ comprises a tubular mounting portion 462, a cable guide channel 461, and a linkage attachment portion 464. In this embodiment, mounting portion 462, cable guide channel 461, and linkage attachment portion 464 are integrally formed as a one-piece, unitary member from a hard, rigid material such as a lightweight metal (e.g. aluminum alloy). As shown in FIG. 15, mounting portion 462 is coaxially mounted on derailleur mounting boss 408 for rotation around a base member axis B. Cable guide channel 461 projects from linkage attachment portion 464 and has a through bore 461 a configured and arranged to receive inner cable 108 therethrough. Through bore 461 a has a center axis that is arranged substantially perpendicular to base member axis B. Linkage attachment portion 464 is a generally U-shaped member that has a pair of mounting flanges 464 a and 464 b with pivot shaft holes for attaching upper and lower links 162 and 166 with pivot shafts 170 and 178.

Mounting portion 462 of base member 70′ comprises a first cylindrical section 468, a second cylindrical section 469, a third cylindrical section 470, and an end wall 473 that extends radially inwardly from first cylindrical section 468 and connects first cylindrical section 468 to second cylindrical section 469 and third cylindrical section 470. An axially extending abutment projection 462 a is disposed at the axially inner end of first cylindrical section 468 for contacting stopper member 448 on derailleur mounting boss 408. When mounting portion 462 is mounted to derailleur mounting boss 408 as shown in FIG. 15, the inner peripheral surface of the axially inner end portion of first cylindrical section 468 contacts outer peripheral surface 453 of derailleur mounting boss 408, the inner peripheral surface of second cylindrical section 469 contacts outer peripheral surface 455, and an annular space is formed between the inner peripheral surface of first cylindrical section 468 and outer peripheral surface 454. Preferably, a metal bushing 480 is disposed in third cylindrical section 470 for contacting outer peripheral surface 455.

A biasing element in the form of a torsion spring 442 is disposed around outer peripheral surface 454 of derailleur mounting boss 408. Spring 442 has a first end 482 and a second end 483, wherein first end 482 is fitted within an opening 459 formed in end face 457 of derailleur mounting boss 408, and second end 483 is fitted within an opening 460 formed in end wall 473 of mounting portion 462 of base member 70′. Openings 459 and 460 are circumferentially oriented relative to each other to provide a counterclockwise biasing force to base member 70′.

Cable guide unit 400 comprises a cable guide mounting member 490, a cable guide in the form of a cable guide roller 491, and a fastener 492. Cable guide mounting member 490 includes an unthreaded opening 497 for receiving bolt 451, an unthreaded opening 499 for receiving fastener 492, a threaded opening 500 for threadingly engaging fastener 492, three arcuate recesses 498 for engaging the three arcuate projections 450 on derailleur mounting boss 408, and an outer casing receiving recess 496 for receiving outer casing 106 of Bowden cable 110 therein. When fixing bolt 451 is passed through opening 497 in cable guide mounting member 490 and screwed into fastener opening 449 with projections 450 disposed in recesses 498, cable guide mounting member 490 is nonrotatably secured to derailleur mounting boss 408.

Cable guide roller 491 includes a wire guide groove 491 a and a tubular bearing 491 b fitted within an opening 491 c. When fastener 492 is passed through opening 499 in cable guide mounting member 490 and through tubular bearing 491 b and is screwed into threaded opening 500, cable guide roller 491 is mounted to cable guide mounting member 490 for rotation around a cable guide axis C that is substantially parallel to and offset from base member axis B. As shown in FIG. 14 wire guide groove 491 a intersects a pivot area A defined by opening 497 in derailleur mounting boss 408 when viewed in a direction along base member axis B.

As shown more clearly in FIG. 14, outer casing receiving recess 496 has a step-shaped configuration with its center axis aligned with wire groove 491 a of cable guide roller 491. Outer casing receiving recess 496 is configured and arranged to contact the end of outer casing 106 so that inner cable 108 extends out of outer casing 106, through the small portion of the outer casing receiving recess 496, and around a portion of the perimeter of cable guide roller 491. Inner cable then exits cable guide roller 491 and is attached to cable clamp 404 on upper link 162.

It should be readily apparent that derailleur mounting boss 408 and cable guide mounting member 490 of cable guide unit 400 are stationary (non-movable) relative to extension member 330′ and frame 14′. On the other hand, base member 70′ is rotatably mounted on derailleur mounting boss 408 so that base member 70′, linking mechanism 82, movable member 74 and chain guide 78 all move together about base member axis B. Since wire guide groove 491 a intersects the pivot area A defined by opening 497 in derailleur mounting boss 408 when viewed in a direction along base member axis B, inner cable 110 is not pulled when base member 70′ rotates around base member axis B. This prevents unwanted lateral movement of movable member 74 and chain guide 78 during such rotation.

While the above is a description of various embodiments of inventive features, further modifications may be employed without departing from the spirit and scope of the present invention. For example, the size, shape, location or orientation of the various components may be changed as desired. Components that are shown directly connected or contacting each other may have intermediate structures disposed between them. The functions of one element may be performed by two, and vice versa. The function of one element may be performed by another, and functions may be interchanged among the elements. The structures and functions of one embodiment may be adopted in another embodiment. It is not necessary for all advantages to be present in a particular embodiment at the same time. Every feature which is unique from the prior art, alone or in combination with other features, also should be considered a separate description of further inventions by the applicant, including the structural and/or functional concepts embodied by such feature(s). Thus, the scope of the invention should not be limited by the specific structures disclosed or the apparent initial focus or emphasis on a particular structure or feature. 

1. A bicycle rear derailleur comprising: a base member; a movable member that supports a chain guide including a first pulley that rotates around a first pulley axis, wherein the pulley has a pulley plane; a first linking member coupled between the base member and the movable member so that the chain guide moves laterally relative to the base member between a first lateral position and a second lateral position; and a cable guide structured to guide a shift control cable; wherein the pulley plane intersects the first linking member when the chain guide is located at a first position between the first lateral position and the second lateral position.
 2. The derailleur according to claim 1 wherein the base member is structured to be mounted relative to a bicycle frame for rotation around a base member axis.
 3. The derailleur according to claim 2 further comprising a biasing element for biasing the base member in a selected rotational direction.
 4. The derailleur according to claim 1 wherein the cable guide is structured to change a direction of the shift control cable.
 5. The derailleur according to claim 4 wherein the cable guide rotates relative to the base member.
 6. The derailleur according to claim 5 wherein the cable guide comprises a cable guide roller that rotates around a cable guide axis.
 7. The derailleur according to claim 6 wherein the base member is structured to be mounted relative to a bicycle frame for rotation around a base member axis.
 8. The derailleur according to claim 7 wherein the cable guide axis is substantially parallel to the base member axis.
 9. The derailleur according to claim 8 wherein the cable guide axis is offset from the base member axis.
 10. The derailleur according to claim 1 further comprising a mounting member for mounting to a bicycle frame, wherein the base member is supported to the mounting member.
 11. The derailleur according to claim 10 wherein the cable guide is mounted to the mounting member.
 12. The derailleur according to claim 11 wherein the cable guide rotates relative to the mounting member around a cable guide axis.
 13. The derailleur according to claim 12 wherein the base member is mounted to the mounting member for rotation around a base member axis.
 14. The derailleur according to claim 13 wherein the cable guide axis is substantially parallel to the base member axis.
 15. The derailleur according to claim 14 wherein the cable guide axis is offset from the base member axis.
 16. The derailleur according to claim 13 further comprising a cable guide mounting member immovably coupled to the mounting member, wherein the cable guide is rotatably mounted to the cable guide mounting member.
 17. The derailleur according to claim 16 wherein the cable guide comprises a cable guide roller that rotates around a cable guide axis.
 18. The derailleur according to claim 17 further comprising a biasing element for biasing the base member in a selected rotational direction relative to the mounting member.
 19. The derailleur according to claim 18 wherein the mounting member comprises an elongated extension member.
 20. The derailleur according to claim 19 wherein the mounting member is structured to be mounted directly to the bicycle frame. 